Sound propagation indoors


Direct and Reflected sound



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Direct and Reflected sound


In many kinds of enclosed spaces, the sound propagates in a peculiar way, very different from what happens outside (even if there are obstacles or sound barriers that can cause reflection). There still is a free field sound (direct waves) where waves travel directly from the source to the receiver. Of course if it is a point source the sound propagates with spherical waves; if a line one, with cylindrical waves.

But this is not the only sound. It is not even the most relevant one.



In most cases much more energy arrives to the receiver by a significant contribution due to room reflections: the sound bounces over the walls, floor etc. (reflected waves).

Fig.01 – different types of waves

In Fig.01, for example, sound is bouncing over the ceiling and a wall before reaching the receiver; surely there will be multiple reflections, also several times, with different and strange trajectories acting like a so-called “acoustic billiard”.

So there is a significant contribution to the sound field due to reflected waves.



There is a strict relationship with light, which can reflect specularly (mirror) or diffusely (white plastered wall).

The chart above, known as “reflectogram”, shows what happens inside a room by means of a so-called energetic impulse response. As a metter of fact the source has radiated an impulse (a hand clap for example) with a length of 2-3 milliseconds. Outdoor the response should have been different: just one peak, followed by silence, as before.

Inside a room, we do not ear only the direct sound: that is just the first sound we ear. After a while, reflections arrive from different ways that we’re not able to know because pressure is an omnidirectional quantity, not a vector. Every peak in the chart is a discrete room reflection making longer and longer paths, arriving weaker and weaker.

So the sound pressure level inside a room can be given by two contributions: direct sound and reflected sound. In some cases one dominates on the other, but, in general, we have to keep both.

Properties of materials


The reflected energy depends on the nature of the surface: there are strongly reflective materials, so they reflect almost 100% of the energy. On the other hand, other materials are “acoustic absorbers”, like a carpet. This last kind of materials can be really useful in order to reduce sound pressure level inside a room by reducing the amount of reflected energy.

Let’s consider a wall for example (fig.02), which is separating two different rooms. When a sound source is placed on the left hand side room, the sound bounces over the separation wall and some energy is reflected, coming back in the source room. Some energy is dissipated inside wall’s material. Another quantity of energy passes through the wall and the sound can be heard in the next room (like we can ear an aircraft flying over our house).



So energy is divided into three contributions: reflected energy, absorbed energy and transmitted energy.

Fig.02 – sound energy subdivision over a wall
This also happens for light and electromagnetic waves (e.g. radio waves)

We can now define 3 numerical coefficients (reflection, absorption and transmission coefficients)


r=Wr/W0 , a=Wa/W0, t=Wt/W0
Their sum must be one because of the energy conservation principle.
r + a + t =1
Of consequence, their value is bounded between 0 and 1.
0 < r,a,t < 1
A very reflecting surface (like a window glass) will have r=1; a,t=0. An open window is completely transmitting so t=1; r,a=0.

Acousticians, however, do not employ any of these three numbers. They only use the so called “apparent acoustic absorption coefficient” , defined as

 = 1 - r (1)
It expresses the energy which has not been reflected. That energy can be absorbed (a) or it can be transmitted (t). So it is possible to write  also as:
 = a + t (2)
An open window has a unit value of .

A perfect reflecting material has  = 0.

All we need to know about the materials covering a room (ceiling, walls, floor etc.) is the apparent absorption coefficient .



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